一种有效的困难样本学习策略

doi:10.19665/j.issn1001-2400.2021.03.013

Abstract

Abstract:

To improve the learning efficiency for hard samples and reduce noise interference caused by superfluous hard samples in deep hash algorithm,a generic strategy called Loss to Gradient for hard sample learning is proposed.First,a non-uniform gradient normalization method is proposed to improve the learning ability of models for hard samples.Back propagation gradients are weighted by calculating the loss ratio between hard samples and all samples.Furthermore,a weighted random sampling method is designed for accuracy improvement with superfluous hard samples.According to the loss,training samples are weighted and under-sampled for noise filtering and a small number of hard samples are retained to avoid over-fitting.Based on open datasets,the average accuracy of hash feature retrieval is increased by 4.7% and 3.4%,respectively.Experimental results show that the improved method outperforms other benchmarking methods in accuracy,proving that the feature representation of hard samples in the dataset can be effectively learned.

Key words: sample analysis, gradient method, hash functions, deep neural networks

CLC Number:

TP183

CAO Yi,CAI Xiaodong. Effective learning strategy for hard samples[J].Journal of Xidian University, 2021, 48(3): 99-105.

Figures/Tables 11

References 16

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对比方法	CIFAR10				SVHN
对比方法	16 bit	24 bit	36 bit	48 bit	16 bit	24 bit	36 bit	48 bit
文中方法	0.736 8	0.750 4	0.765 0	0.763 9	0.723 4	0.735 8	0.752 3	0.753 7
文献[2]方法	0.715 6	0.756 0	0.775 0	0.770 9	0.696 0	0.725 3	0.740 0	0.745 6
文献[4]方法	0.735 9	0.750 6	0.760 9	0.753 7	0.705 0	0.722 7	0.742 6	0.756 6
文献[5]方法	0.719 6	0.705 2	0.717 5	0.699 3	0.732 0	0.735 0	0.739 0	0.736 0
文献[6]方法	0.715 0	0.703 7	0.719 0	0.716 0	0.722 0	0.732 8	0.734 0	0.720 0

对比方法	CIFAR10
对比方法	16 bit	24 bit	36 bit	48 bit
文中方法	0.734	0.727	0.729	0.731
文献[6]方法	0.715	0.7037	0.719	0.716

对比方法	CIFAR10	MNIST
文中方法	0.731	0.988
Softmax	0.712	0.982

对比方法	CIFAR10
对比方法	16 bit	24 bit	36 bit	48 bit
文中方法	0.734	0.752	0.748	0.752
文献[4]方法*	0.728	0.732	0.736	0.746
文献[6]方法	0.715	0.7037	0.719	0.716

对比方法	平均精确度
加权随机采样	0.752
随机采样	0.734
全部采样简单样本	0.101
全部采样困难样本	0.712
文献[6]方法	0.716

Effective learning strategy for hard samples

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References 16

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